Design and analysis of pharmacokinetic and pharmacodynamic trials

Wang, Jixian

January 1998

No description available.

519.5

Drug trials; Statistical design

Catalytic conversion of glycerol to value-added liquid chemicals

Pathak, Kapil Dev

21 November 2005

<p>Glycerol is one of the by-products of transesterification of fatty acids for the production of bio-diesel. Value-added products such as hydrogen, wood stabilizers and liquid chemicals from catalytic treatment of glycerol can improve the economics of the bio-diesel production process. Catalytic conversion of glycerol can be used for production of value-added liquid chemicals. In this work, a systematic study has been conducted to evaluate the effects of operating conditions on glycerol conversion to liquid chemical products in the presence of acid catalysts. </p><p>Central composite design for response surface method was used to design the experimental plan. Experiments were performed in a fixed-bed reactor using HZSM-5, HY, silica-alumina and ã-alumina catalysts. The temperature, carrier gas flow rate and weight hourly space velocity (WHSV) were maintained in the range of 350-500 oC, 20-50 mL/min and 5.40-21.60 h -1, respectively. </p><p>The main liquid chemicals detected in liquid product were acetaldehyde, acrolein, formaldehyde and hydroxyacetone. Under all experimental conditions complete glycerol conversion was obtained over silica-alumina and ã-alumina. A maximum liquid product yield of approximately 83 g/100g feed was obtained with these two catalysts when the operating conditions were maintained at 380 oC, 26 mL/min and 8.68 h-1. Maximum glycerol conversions of 100 wt% and 78.8 wt% were obtained in the presence of HY and HZSM-5 at temperature, carrier gas flow rate and WHSV of 470 oC, 26 mL/min and 8.68 h-1. HY and HZSM-5 produced maximum liquid product of 80.9 and 59.0 g/100 g feed at temperature of 425 and 470 oC, respectively.</p><p>Silica-alumina produced the maximum acetaldehyde (~24.5 g/100 g feed) whereas ã-alumina produced the maximum acrolein (~25 g/100 g feed). Also, silica-alumina produced highest formaldehyde yield of 9g/100 g feed whereas HY produced highest acetol yield of 14.7 g/100 g feed. The effect of pore size of these catalysts was studied on optimum glycerol conversion and liquid product yield. Optimum conversion increased from 80 to 100 wt% and optimum liquid product increased from 59 to 83.3 g/100 g feed when the pore size of catalyst was increased from 0.54 in case of HZSM-5 to 0.74 nm in case of HY, after which the effect of pore size was minimal.

statistical design of experiments

Glycerol

Value-added processing

catalytic conversion

Catalytic conversion of glycerol to value-added liquid chemicals

Pathak, Kapil Dev

21 November 2005

<p>Glycerol is one of the by-products of transesterification of fatty acids for the production of bio-diesel. Value-added products such as hydrogen, wood stabilizers and liquid chemicals from catalytic treatment of glycerol can improve the economics of the bio-diesel production process. Catalytic conversion of glycerol can be used for production of value-added liquid chemicals. In this work, a systematic study has been conducted to evaluate the effects of operating conditions on glycerol conversion to liquid chemical products in the presence of acid catalysts. </p><p>Central composite design for response surface method was used to design the experimental plan. Experiments were performed in a fixed-bed reactor using HZSM-5, HY, silica-alumina and ã-alumina catalysts. The temperature, carrier gas flow rate and weight hourly space velocity (WHSV) were maintained in the range of 350-500 oC, 20-50 mL/min and 5.40-21.60 h -1, respectively. </p><p>The main liquid chemicals detected in liquid product were acetaldehyde, acrolein, formaldehyde and hydroxyacetone. Under all experimental conditions complete glycerol conversion was obtained over silica-alumina and ã-alumina. A maximum liquid product yield of approximately 83 g/100g feed was obtained with these two catalysts when the operating conditions were maintained at 380 oC, 26 mL/min and 8.68 h-1. Maximum glycerol conversions of 100 wt% and 78.8 wt% were obtained in the presence of HY and HZSM-5 at temperature, carrier gas flow rate and WHSV of 470 oC, 26 mL/min and 8.68 h-1. HY and HZSM-5 produced maximum liquid product of 80.9 and 59.0 g/100 g feed at temperature of 425 and 470 oC, respectively.</p><p>Silica-alumina produced the maximum acetaldehyde (~24.5 g/100 g feed) whereas ã-alumina produced the maximum acrolein (~25 g/100 g feed). Also, silica-alumina produced highest formaldehyde yield of 9g/100 g feed whereas HY produced highest acetol yield of 14.7 g/100 g feed. The effect of pore size of these catalysts was studied on optimum glycerol conversion and liquid product yield. Optimum conversion increased from 80 to 100 wt% and optimum liquid product increased from 59 to 83.3 g/100 g feed when the pore size of catalyst was increased from 0.54 in case of HZSM-5 to 0.74 nm in case of HY, after which the effect of pore size was minimal.

statistical design of experiments

Glycerol

Value-added processing

catalytic conversion

Statistical design and analysis of microarray experiments

Wang, Tao

14 July 2005

No description available.

Statistics

microarray

gene expression

statistical analysis

modeling

statistical design

Composição e disgestibilidade enzimática do bagaço de cana-de-açúcar pré-tratado com ácido sulfúrico diluído em reator estático / Composition and enzymatic digestibility of sugarcane bagasse pretreated with dilute sulfuric acid in static reactor

Victor Tabosa de Oliveira Santos

26 November 2010

O presente trabalho teve como principal objetivo correlacionar a composição química do bagaço de cana-de-açúcar pré-tratado com H2SO4 diluído com a eficiência da sacarificação enzimática da celulose presente no material. Primeiramente, o bagaço in natura foi extraído com água, etanol ou água seguida de etanol, e as composições químicas determinadas. Posteriormente, o bagaço in natura foi pré-tratado com H2SO4 diluído em êmbolos de 200 mL, utilizando 15% de teor de sólidos (m/v). A temperatura (112,5-157,5 °C), o tempo de residência (5-35 min) e a concentração ácida (0-3,0% m/v) variaram de acordo com um planejamento fatorial 23 completo. Após o pré-tratamento, as amostras foram caracterizadas quimicamente. Em seguida, dois extratos enzimáticos comerciais foram caracterizados quanto às atividades de enzimas hidrolíticas e fenoloxidases, e aos teores de proteínas. As condições adequadas de sacarificação enzimática da celulose para a amostra de bagaço pré-tratada com H2SO4 diluído (15% sólidos, 2% ácido, a 150ºC por 30 min) foram determinadas através de planejamentos fatoriais 23 completos, variando teor de sólidos (1,19-4,81% m/v), carga enzimática (1,91-38,09 FPU/g de bagaço) e carga de surfactante (0-0,1 g/g de bagaço), para os dois extratos enzimáticos. As amostras de bagaço pré-tratadas sob diferentes condições de temperatura, tempo de residência e concentração de H2SO4 (primeiro planejamento fatorial) foram submetidas à sacarificação enzimática com um dos extratos. Por fim, amostras selecionadas foram caracterizadas quanto às alterações morfológicas provocadas pelo pré-tratamento e pela hidrólise enzimática, por microscopia eletrônica de varredura. Os resultados mostraram que água seguida de etanol extraiu maior quantidade de extrativos do bagaço. Os extrativos apresentaram absorção de luz apenas na região do ultravioleta. A porcentagem de lignina nos bagaços extraídos com água, etanol e água seguida de etanol foi menor que aquela encontrada no bagaço in natura. De acordo com a condição de pré-tratamento, os teores de celulose, hemicelulose e lignina nos bagaços pré-tratados diferiram substancialmente. A maior variação foi observada para hemicelulose (3,67-27,27%). Os três fatores avaliados no pré-tratamento influenciaram na composição química do bagaço pré-tratado. Por sua vez, os dois extratos enzimáticos apresentaram um complexo celulolítico completo e considerável atividade de xilanases, porém não foi observada atividade de fenoloxidases. O extrato II apresentou maior quantidade de proteínas (152,45±10,0 mg/mL), comparado ao extrato I (105,2±6,6 mg/mL). Para 24 horas de hidrólise enzimática com o extrato I, as três variáveis independentes influenciaram na digestão do bagaço pré-tratado. Somente os efeitos das cargas de enzima e surfactante foram significantes, utilizando o extrato II. Posteriormente, foi possível aumentar o teor inicial de sólidos sem comprometer o rendimento de sacarificação com o extrato II. Não foi possível correlacionar a conversão de celulose com o fator de severidade do pré-tratamento. Por outro lado, foi observada correlação negativa entre o conteúdo de hemicelulose e a conversão enzimática de celulose, enfatizando a influência da composição química do bagaço de cana na hidrólise enzimática da celulose. Observaram-se diferenças morfológicas entre o bagaço in natura e amostras pré-tratadas sob condições branda e severa, bem como após suas respectivas hidrólises enzimáticas. / This study aimed to correlate the chemical composition of a sugarcane bagasse pretreated with dilute H2SO4 with the efficiency of cellulose enzymatic saccharification of this material. First, the sugarcane bagasse was extracted with water, ethanol or water followed by ethanol, and its chemical composition was determined. Subsequently, the sugarcane bagasse was pretreated with dilute H2SO4 in 200 mL stainless steel containers, using 15% of solids loading (w/v). The temperature (112.5-157.5°C), time of residence (5-35 min) and acid concentration (0-3.0% w/v) varied according to a 23 full factorial design. After the pretreatments, the chemical compositions of the pretreated bagasses were determined. Then, two commercial enzymatic extracts were characterized regarding the activities of hydrolytic enzymes and phenoloxidases, and protein contents. The enzymatic saccharification conditions for the bagasse sample pretreated with dilute H2SO4 (15% solids, 2% acid, 150°C for 30 min) were determined through 23 full factorial designs, varying the solids loading (1,19-4.81% w/v), enzyme loading (1.91-38.09 FPU/g of bagasse) and surfactant loading (0-0.1 g/g of bagasse) for the two enzymatic extracts. The bagasse samples pretreated under the different conditions of temperature, time of residence and H2SO4 concentration (first factorial design) were subjected to enzymatic saccharification using one of the extracts. Finally, selected samples were analyzed for morphological changes caused by pretreatment and enzymatic hydrolysis, by scanning electron microscopy. The results showed that water followed by ethanol extracted the highest amount of extractives. The extractives showed light absorption only in the ultraviolet region. The percentage of lignin in the bagasse samples extracted with water, ethanol and water followed by ethanol was lower than that found in the raw material. According to the pretreatment conditions, the amount of cellulose, hemicellulose and lignin in the pretreated bagasse differed substantially. The greatest variation was observed for the hemicellulose content (3.67-27.27%). All the three factors evaluated in the pretreatment affected the chemical composition of the pretreated bagasse. In turn, the two enzymatic extracts showed complete cellulolytic complexes and considerable activities of xylanases, without activities of phenoloxidases. The extract II showed higher protein content (152.45±10.0 mg/mL) when compared with the extract I (105.2±6.6 mg/mL). For 24 hours of enzymatic hydrolysis using the extract I, all the three independent variables influenced the saccharification of pretreated bagasse. Only the enzyme and surfactant loadings were significant, when using the extract II. Later, it was possible to increase the initial solids content without hindering the saccharification yield, using the extract II. It was not possible to correlate the cellulose conversion with the pretreatment severity. On other hand, it was possible to observe a negative correlation between the hemicellulose content and the efficiency of enzymatic conversion, emphasizing the influence of the sugarcane bagasse chemical composition in the enzymatic hydrolysis of cellulose. Morphological differences were observed between the raw material and sugarcane bagasse samples pretreated under high or low severity, as well as after their corresponding enzymatic hydrolysis.

bagaço de cana-de-açúcar

celulases

hidrólise enzimática

planejamento experimental.

Cellulases. Enzymatic hydrolysis

Statistical design

Sugarcane bagasse

Composição e disgestibilidade enzimática do bagaço de cana-de-açúcar pré-tratado com ácido sulfúrico diluído em reator estático / Composition and enzymatic digestibility of sugarcane bagasse pretreated with dilute sulfuric acid in static reactor

Santos, Victor Tabosa de Oliveira

26 November 2010

O presente trabalho teve como principal objetivo correlacionar a composição química do bagaço de cana-de-açúcar pré-tratado com H2SO4 diluído com a eficiência da sacarificação enzimática da celulose presente no material. Primeiramente, o bagaço in natura foi extraído com água, etanol ou água seguida de etanol, e as composições químicas determinadas. Posteriormente, o bagaço in natura foi pré-tratado com H2SO4 diluído em êmbolos de 200 mL, utilizando 15% de teor de sólidos (m/v). A temperatura (112,5-157,5 °C), o tempo de residência (5-35 min) e a concentração ácida (0-3,0% m/v) variaram de acordo com um planejamento fatorial 23 completo. Após o pré-tratamento, as amostras foram caracterizadas quimicamente. Em seguida, dois extratos enzimáticos comerciais foram caracterizados quanto às atividades de enzimas hidrolíticas e fenoloxidases, e aos teores de proteínas. As condições adequadas de sacarificação enzimática da celulose para a amostra de bagaço pré-tratada com H2SO4 diluído (15% sólidos, 2% ácido, a 150ºC por 30 min) foram determinadas através de planejamentos fatoriais 23 completos, variando teor de sólidos (1,19-4,81% m/v), carga enzimática (1,91-38,09 FPU/g de bagaço) e carga de surfactante (0-0,1 g/g de bagaço), para os dois extratos enzimáticos. As amostras de bagaço pré-tratadas sob diferentes condições de temperatura, tempo de residência e concentração de H2SO4 (primeiro planejamento fatorial) foram submetidas à sacarificação enzimática com um dos extratos. Por fim, amostras selecionadas foram caracterizadas quanto às alterações morfológicas provocadas pelo pré-tratamento e pela hidrólise enzimática, por microscopia eletrônica de varredura. Os resultados mostraram que água seguida de etanol extraiu maior quantidade de extrativos do bagaço. Os extrativos apresentaram absorção de luz apenas na região do ultravioleta. A porcentagem de lignina nos bagaços extraídos com água, etanol e água seguida de etanol foi menor que aquela encontrada no bagaço in natura. De acordo com a condição de pré-tratamento, os teores de celulose, hemicelulose e lignina nos bagaços pré-tratados diferiram substancialmente. A maior variação foi observada para hemicelulose (3,67-27,27%). Os três fatores avaliados no pré-tratamento influenciaram na composição química do bagaço pré-tratado. Por sua vez, os dois extratos enzimáticos apresentaram um complexo celulolítico completo e considerável atividade de xilanases, porém não foi observada atividade de fenoloxidases. O extrato II apresentou maior quantidade de proteínas (152,45±10,0 mg/mL), comparado ao extrato I (105,2±6,6 mg/mL). Para 24 horas de hidrólise enzimática com o extrato I, as três variáveis independentes influenciaram na digestão do bagaço pré-tratado. Somente os efeitos das cargas de enzima e surfactante foram significantes, utilizando o extrato II. Posteriormente, foi possível aumentar o teor inicial de sólidos sem comprometer o rendimento de sacarificação com o extrato II. Não foi possível correlacionar a conversão de celulose com o fator de severidade do pré-tratamento. Por outro lado, foi observada correlação negativa entre o conteúdo de hemicelulose e a conversão enzimática de celulose, enfatizando a influência da composição química do bagaço de cana na hidrólise enzimática da celulose. Observaram-se diferenças morfológicas entre o bagaço in natura e amostras pré-tratadas sob condições branda e severa, bem como após suas respectivas hidrólises enzimáticas. / This study aimed to correlate the chemical composition of a sugarcane bagasse pretreated with dilute H2SO4 with the efficiency of cellulose enzymatic saccharification of this material. First, the sugarcane bagasse was extracted with water, ethanol or water followed by ethanol, and its chemical composition was determined. Subsequently, the sugarcane bagasse was pretreated with dilute H2SO4 in 200 mL stainless steel containers, using 15% of solids loading (w/v). The temperature (112.5-157.5°C), time of residence (5-35 min) and acid concentration (0-3.0% w/v) varied according to a 23 full factorial design. After the pretreatments, the chemical compositions of the pretreated bagasses were determined. Then, two commercial enzymatic extracts were characterized regarding the activities of hydrolytic enzymes and phenoloxidases, and protein contents. The enzymatic saccharification conditions for the bagasse sample pretreated with dilute H2SO4 (15% solids, 2% acid, 150°C for 30 min) were determined through 23 full factorial designs, varying the solids loading (1,19-4.81% w/v), enzyme loading (1.91-38.09 FPU/g of bagasse) and surfactant loading (0-0.1 g/g of bagasse) for the two enzymatic extracts. The bagasse samples pretreated under the different conditions of temperature, time of residence and H2SO4 concentration (first factorial design) were subjected to enzymatic saccharification using one of the extracts. Finally, selected samples were analyzed for morphological changes caused by pretreatment and enzymatic hydrolysis, by scanning electron microscopy. The results showed that water followed by ethanol extracted the highest amount of extractives. The extractives showed light absorption only in the ultraviolet region. The percentage of lignin in the bagasse samples extracted with water, ethanol and water followed by ethanol was lower than that found in the raw material. According to the pretreatment conditions, the amount of cellulose, hemicellulose and lignin in the pretreated bagasse differed substantially. The greatest variation was observed for the hemicellulose content (3.67-27.27%). All the three factors evaluated in the pretreatment affected the chemical composition of the pretreated bagasse. In turn, the two enzymatic extracts showed complete cellulolytic complexes and considerable activities of xylanases, without activities of phenoloxidases. The extract II showed higher protein content (152.45±10.0 mg/mL) when compared with the extract I (105.2±6.6 mg/mL). For 24 hours of enzymatic hydrolysis using the extract I, all the three independent variables influenced the saccharification of pretreated bagasse. Only the enzyme and surfactant loadings were significant, when using the extract II. Later, it was possible to increase the initial solids content without hindering the saccharification yield, using the extract II. It was not possible to correlate the cellulose conversion with the pretreatment severity. On other hand, it was possible to observe a negative correlation between the hemicellulose content and the efficiency of enzymatic conversion, emphasizing the influence of the sugarcane bagasse chemical composition in the enzymatic hydrolysis of cellulose. Morphological differences were observed between the raw material and sugarcane bagasse samples pretreated under high or low severity, as well as after their corresponding enzymatic hydrolysis.

bagaço de cana-de-açúcar

Cellulases. Enzymatic hydrolysis

celulases

hidrólise enzimática

planejamento experimental.

Statistical design

Sugarcane bagasse

High Performance Digital Circuit Techniques

Sadrossadat, Sayed Alireza

January 2009

Achieving high performance is one of the most difficult challenges in designing digital circuits. Flip-flops and adders are key blocks in most digital systems and must therefore be designed to yield highest performance. In this thesis, a new high performance serial adder is developed while power consumption is attained. Also, a statistical framework for the design of flip-flops is introduced that ensures that such sequential circuits meet timing yield under performance criteria. Firstly, a high performance serial adder is developed. The new adder is based on the idea of having a constant delay for the addition of two operands. While conventional adders exhibit logarithmic delay, the proposed adder works at a constant delay order. In addition, the new adder's hardware complexity is in a linear order with the word length, which consequently exhibits less area and power consumption as compared to conventional high performance adders. The thesis demonstrates the underlying algorithm used for the new adder and followed by simulation results. Secondly, this thesis presents a statistical framework for the design of flip-flops under process variations in order to maximize their timing yield. In nanometer CMOS technologies, process variations significantly impact the timing performance of sequential circuits which may eventually cause their malfunction. Therefore, developing a framework for designing such circuits is inevitable. Our framework generates the values of the nominal design parameters; i.e., the size of gates and transmission gates of flip-flop such that maximum timing yield is achieved for flip-flops. While previous works focused on improving the yield of flip-flops, less research was done to improve the timing yield in the presence of process variations.

Electrical and Computer Engineering

High Performance Digital Circuit Techniques

Sadrossadat, Sayed Alireza

January 2009

Achieving high performance is one of the most difficult challenges in designing digital circuits. Flip-flops and adders are key blocks in most digital systems and must therefore be designed to yield highest performance. In this thesis, a new high performance serial adder is developed while power consumption is attained. Also, a statistical framework for the design of flip-flops is introduced that ensures that such sequential circuits meet timing yield under performance criteria. Firstly, a high performance serial adder is developed. The new adder is based on the idea of having a constant delay for the addition of two operands. While conventional adders exhibit logarithmic delay, the proposed adder works at a constant delay order. In addition, the new adder's hardware complexity is in a linear order with the word length, which consequently exhibits less area and power consumption as compared to conventional high performance adders. The thesis demonstrates the underlying algorithm used for the new adder and followed by simulation results. Secondly, this thesis presents a statistical framework for the design of flip-flops under process variations in order to maximize their timing yield. In nanometer CMOS technologies, process variations significantly impact the timing performance of sequential circuits which may eventually cause their malfunction. Therefore, developing a framework for designing such circuits is inevitable. Our framework generates the values of the nominal design parameters; i.e., the size of gates and transmission gates of flip-flop such that maximum timing yield is achieved for flip-flops. While previous works focused on improving the yield of flip-flops, less research was done to improve the timing yield in the presence of process variations.

Electrical and Computer Engineering

A strategy for ranking environmentally occuring chemicals

Eriksson, Lennart

January 1991

A systematic methodology for quantitative structure-activity relationship (QSAR) development in environmental toxicology is provided. The methodology is summarized in a strategy with six sequential steps. The strategy rests on two cornerstones, namely (1) the use of statistical design to select a series of representative compounds (the so-called training set) on which to base a QSAR, and (2) the multivariate modelling of the relationship between physicochemical and biological properties of the training set compounds. The first step of the strategy is the division of chemicals into classes of structurally similar compounds. Briefly, steps 2 to 6 are: (2) physico-chemical and structural characterization of the compounds in a class, (3) selection of a training set of representative compounds, (4) biological testing of the selected training set, (5) QSAR model development, and (6) experimental validation of the QSAR and predictions for non-tested compounds. The thesis summarizes the results obtained from the application of the strategy to the class of halogenated aliphatic compounds. Biological measurements were made in four biological test systems, reflecting acute toxicity, mutagenicity, relative cytotoxicity and genotoxicity. QSARs were developed relating each biological endpoint to the structural descriptors of the compounds. Multivariate PLS modelling was used in the data analysis. The developed QSARs were used for predicting the biological activity pattern of the non-tested compounds in the class. These predictions may be used as a starting point for a priority ranking for further biological testing of these compounds. The strategy has not been developed solely for establishing QSARs for the halogenated aliphatics class. On the contrary, this work is intended to demonstrate a generally applicable QSAR methodology. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1991</p> / digitalisering@umu

QSAR

hazard ranking

statistical design

multivariate modelling

halogenated aliphatics

PCA

PLS

Robust Design Of Lithium Extraction From Boron Clays By Using Statistical Design And Analysis Of Experiments

Buyukburc, Atil

01 January 2003

In this thesis, it is aimed to design lithium extraction from boron clays using statistical design of experiments and robust design methodologies. There are several factors affecting extraction of lithium from clays. The most important of these factors have been limited to a number of six which have been gypsum to clay ratio, roasting temperature, roasting time, leaching solid to liquid ratio, leaching time and limestone to clay ratio. For every factor, three levels have been chosen and an experiment has been designed. After performing three replications for each of the experimental run, signal to noise ratio transformation, ANOVA, regression analysis and response surface methodology have been applied on the results of the experiments. Optimization and confirmation experiments have been made sequentially to find factor settings that maximize lithium extraction with minimal variation. The mean of the maximum extraction has been observed as 83.81% with a standard deviation of 4.89 and the 95% prediction interval for the mean extraction is (73.729, 94.730). This result is in agreement with the studies that have been made in the literature. However / this study is unique in the sense that lithium is extracted from boron clays by using limestone directly from the nature, and gypsum as a waste product of boric acid production. Since these two materials add about 20% cost to the extraction process, the results of this study become important. Moreover, in this study it has been shown that statistical design of experiments help mining industry to reduce the need for standardization.